Add the platform conditional and set up other basics for the toolchain.
The ConditionalCompilation tests are updated to match, since otherwise
they seem to trip when building on non-OpenBSD platforms. The
Driver/linker test is updated to ensure lld is passed on this platform.
Note that OpenBSD calls "x86_64" as "amd64", so we use that name for the
architecture instead of trying to alias one to the other, as this makes
things simpler.
Add support in the driver and frontend for macCatalyst target
targets and library search paths.
The compiler now adds two library search paths for overlays when compiling
for macCatalyst: one for macCatalyst libraries and one for zippered macOS
libraries. The macCatalyst path must take priority over the normal macOS path
so that in the case of 'unzippered twins' the macCatalyst library is
found instead of the macOS library.
To support 'zippered' builds, also add support for a new -target-variant
flag. For zippered libraries, the driver invocation takes both a -target and a
-target-variant flag passes them along to the frontend. We support builds both
when the target is a macOS triple and the target variant is macCatalyst and
also the 'reverse zippered' configuration where the target is macCatalyst and the
target-variant is macOS.
The android API level can be ignored when loading the module. The API
level controls the NDK APIs which are available and is equivalent to the
SDK version for Darwin. This allows us to keep the API level in the
triple which future versions of Android's toolchain does.
The backwards-deployment install name trickery we're using doesn't
handle "patch" components in version numbers, so we still need to
provide an rpath even when deploying to macOS 10.14.4.
Many build systems that support Swift don't use swiftc to drive the linker. To make things
easier for these build systems, also use autolinking to pull in the needed compatibility
libraries. This is less ideal than letting the driver add it at link time, since individual
compile jobs don't know whether they're building an executable or not. Introduce a
`-disable-autolink-runtime-compatibility` flag, which build systems that do drive the linker
with swiftc can pass to avoid autolinking.
rdar://problem/50057445
When loading a module supporting multiple targets, the module loader now looks for a file named with a normalized version of the target triple first, and only falls back to the architecture name if the normalized triple is not found.
LLVM r340675 added a new HermitCore OS type to triples, which broke the
Swift build because it is using -Werror,-Wswitch and the new value was not
handled in swift::getPlatformNameForTriple
This silences the instances of the warning from Visual Studio about not all
codepaths returning a value. This makes the output more readable and less
likely to lose useful warnings. NFC.
LLVM r340675 added a new HermitCore OS type to triples, which broke the
Swift build because it is using -Werror,-Wswitch and the new value was not
handled in swift::getPlatformNameForTriple
> warning C4062: enumerator 'llvm::Triple::Fuchsia' in switch of enum
'llvm::Triple::OSType' is not handled
> warning C4062: enumerator 'llvm::Triple::Contiki' in switch of enum
'llvm::Triple::OSType' is not handled
> warning C4062: enumerator 'llvm::Triple::LastOSType' in switch of enum
'llvm::Triple::OSType' is not handled
Fixed for the difference of Cygwin with other Windows variants (MSVC,
Itanium, MinGW).
- The platform name is renamed to "cygwin" from "windows" which is used
for searching the standard libraries.
- The consideration for DLL storage class (DllExport/DllImport) is not
required for Cygwin and MinGW. There is no problem when linking in
these environment.
- Cygwin should use large memory model as default.(This may be changed
if someone ports to 32bit)
- Cygwin and MinGW should use the autolink feature in the sameway of
Linux due to the linker's limit.
Rather than have a series of cascading if conditionals, use a switch. Although
Darwin and android are special, they can be handled just as cleanly in the
switch version. NFC.
On the Raspberry Pi 2 when trying to import Glibc, without this patch, it will attempt to
find the module map at "/usr/lib/swift/linux/armv7l/glibc.modulemap" and
fail to do so.
With this patch it will attempt to find the module map at
"/usr/lib/swift/linux/armv7/glibc.modulemap" where it will succeed in
finding the module map.
Similar behavior currently happens in the Driver and Frontend. To DRY up
this behavior it has been extracted to the Swift platform.
